The disclosure generally relates to a method for producing a fibre-based building panel, preferably a floor panel, and to a building panel produced by said method.
A new type of panel called Wood Fiber Floor (WFF) is disclosed in WO2009/065769, which shows both products and methods to produce such a panel. Further methods and production equipments are disclosed in WO2009/124704.
The WFF floor panels are produce by applying a dry powder mix on a HDF core. The powder mix is bonded together under heat and pressure to form a decorative surface layer.
In order to stabilize the dry powder mix the production methods in WO2009/065769 or in WO2009/124704 (see page 15, line 15-21; FIG. 3) uses spraying of pure water or water with additives.
The entire contents of WO2009/065769 and WO2009/124704 are hereby incorporated by reference herein, and with a specific reference to page 15, line 15-21 and FIG. 3 of WO2009/124704.
An objective of embodiments of the disclosure is to provide production methods that are more effective than the present known technology. Another objective is to produce panels with a more uniform colour or a more controlled colour variation and/or pattern.
When pressing a surface layer out of powder mix—such as a WFF mixture disclosed in WO2009/065769 or in WO2009/124704—one problem is to avoid that the powder mixture completely or partly blows off when the board is handled in the line before pressing and/or blow out of the press when the air is evacuated due to the closing of the press.
The known solutions to stabilize the powder by using spraying of water has the disadvantage that it is difficult to control the distribution of the water and to avoid water drops unintentionally falling down on the powder layer from the spraying unit.
An uneven water distribution and/or unintentional water drops normally have a negative effect of the visual as well as technical properties of the product. Furthermore, a waiting time to let the water penetrate into the powder before entering the press slow down the press cycle and to total out put from the production line is lowered.
A first aspect of the disclosure is a method of manufacturing a panel comprising a core (1) and a decorative surface layer (4) comprising the steps of:
The steam is preferably a water steam, most preferably a substantially pure water steam, even though the steam may comprise one or more additives. Examples of additives are wetting agents, releasing agents and/or colour additives.
The dry powder layer is preferably a mix of fibres, preferably wood fibres, and binder(s). The powder layer may also include wear resistant particles, preferably aluminium oxide.
The core is preferably a wood fibre based core, preferably an HDF panel.
A second aspect of the disclosure is a method of manufacturing a panel comprising a core (1) and a surface layer (4) with a designed pattern comprising the steps of:
The steam in the first and the second aspect is preferably a water steam, most preferably a substantially pure water steam, even though the steam may comprise one or more additives. The steam may be a mist or the gas phase of water (water vapour), preferably a saturated vapour and most preferably a saturated vapour mainly comprising water.
Preferred embodiments of the first and second aspects of the disclosure are disclosed below.
A third aspect of the disclosure is a panel produced according to any one the aspects above.
The methods above may be used to any production of a building panel in which a dry powder layer is applied to a core.
The disclosure will in the following be described in connection to exemplary embodiments and in greater detail with reference to the appended exemplary drawings, wherein:
In
In the methods according to the present disclosure preferably the same scattering and pressing units as disclosed in WO2009/065769 or in WO2009/124704 are used.
In one embodiment the steam is applied by using a steam box 8, a box with one or more outlets at the bottom for steam, positioned above the transportation belt. The box preferably extends across the panel with a uniform width. An even moisture distribution is applied over the surface of the scattered powder layer 2, when the board pass under the steam box. Since the steam penetrate into the powder very effectively it is possible to immediately move the board into the press and close the press 9.
A suitable steam box is either fed by an external steam generator or the steam is generated in the steam box itself. It is suitable that that the steambox is equipped with one or several layers of nets for example mesh and/or sheets with holes to even out the steam concentration close to the powder layer.
By controlling the relative movement between a core 1 with the powder mix layer 2 and one or several steam outlets a controlled variation of the content of moisture 21 in the powder can be achieved. This variation of moisture content will after pressing be visible as color differences 22 on the ready surface 24.
One or several of the steam outlets could be fixed on a robot arm and their position in relation to the scattered board could then be controlled in all directions.
The steam outlets 41 could be positioned in a rotating device, preferably a steam pipe 40, to generate a controlled moisture variation 42 in the powder layer 2, see
As a Non-Limiting Example, the Steps for Producing a WFF Board could be as Follows:
In an alternative example also one or more paper sheets are applied after step 4.
An Example of a Production of a WFF Board with a Designed Pattern by Controlled Uneven Moisture Distribution:
In an alternative example also one or more paper sheets are applied after step 4.
The present application is a continuation of U.S. application Ser. No. 13/118,846, filed on May 31, 2011, which claims the benefit of U.S. Provisional Application No. 61/349,950, filed on May 31, 2010. The entire contents of each of U.S. application Ser. Nos. 13/118,846 and 61/349,950 are hereby incorporated by reference herein.
Number | Date | Country | |
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61349950 | May 2010 | US |
Number | Date | Country | |
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Parent | 13118846 | May 2011 | US |
Child | 16395289 | US |